RU2690207C1 - Method for magnetotelluric sounding of geological structures - Google Patents

Abstract

FIELD: geoelectric prospecting.SUBSTANCE: invention relates to geoelectric prospecting and can be used for studying structure of earth's crust. Multidirectional electric and magnetic components of the magnetotelluric field are measured at the surface of the Earth, from which partial impedances of waves of magnetic and electric type are determined, and distribution of conductivity of the horizontally layered section of the earth's crust in the upper mantle is determined. Measuring device for extraction of vertical electrical component in natural magnetotelluric field is performed by circular electric dipole scheme, for this purpose, horizontal radial earthed lines converging to the centre through equal angular intervals are placed with a radius corresponding to depth of investigation, and grounded at external ends and common central electrode. Measuring device can be located on the sea surface by means of floating buoys or on the drifting ice, and electrodes are grounded through holes in ice.EFFECT: high efficiency of magnetotelluric sounding when observing weak lateral inhomogeneities.3 cl, 4 dwg

Description

The invention relates to geoelectromagnetic method of magnetotelluric sensing and can be used to study the complex structure of the earth's crust.

There is a method of electrical prospecting (SU No. 1062531 Geoelectromagnetic method / Mogilatov BC; publ. 23.12.83, Byul. No. 47), in which an electric field is excited in the Earth by axisymmetric introduction of electric current to the Earth and the parameters of the electric field are measured by profiles radially diverging from point of introduction of axisymmetric electric current in the Earth. In this case, the axisymmetric introduction of current into the Earth is ensured by the uniform arrangement of external supply electrodes (grounding) around the circumference and their connection by radial lines to one pole of the current source. The radius of a circle is determined by the required depth of investigation. In this case, the internal supply electrode is grounded at the center of the circle formed by the external supply electrodes, and connected to the other pole of the current source. Such a source since the publication of the method is called a circular electric dipole (QED). On the basis of the known method, the method of sensing by vertical currents (SVT), shown in FIG. 1, and which belongs to the methods of electrical prospecting with controlled sources.

The role of such a specific source is that a special polarization of the electromagnetic field is created in the Earth - a transverse magnetic (TM), the main feature of which is the presence of a vertical electrical component. Because of this, the field of such a source is very sensitive to objects of increased resistance, as well as generally to horizontal inhomogeneities in the section.

It should be noted that the reverse is also true: - if QED is used as a receiver, then it is possible to isolate the contribution of the TM field from an arbitrary electromagnetic field or, in other words, determine the vertical component of the electric field, which is highly desirable to measure in the MTS.

There is a method of magnetotelluric sounding (Savin MG, author's certificate SU 1323993, published. 07.15.1987, Bull. No. 26), further adopted as a prototype in which four horizontal and two vertical field components are measured on the surface of the Earth, denoted respectively through E _x , E _y , H _x , H _y and E _z , H _z , where E _{x, y, z are} electrical, a H _{x, y, z are the} magnetic components of the magnetotelluric field; from these measurements, the complex spectral amplitudes of the spatial components of the magnetotelluric field at the frequency ω are found; using the six complex spectral amplitudes of the spatial components of the field, determine the horizontal field heterogeneity of the sources, characterized by the rate of horizontal propagation of geomagnetic pulsations along the Earth’s surface, and the corresponding impedances, which are then judged on the electrical structure of the Earth’s crust.

The disadvantages of this prototype method include the difficulty of measuring the component E _z (vertical electrical component). The fact is that in order to ensure the noise immunity of measurements of E _z in the working area of geomagnetic pulsations (tens to hundreds of seconds) with respect to random charges of hydrometeors, it is necessary to carry out measurements of E _z in wells, which complicates measurements, for example, when wells are drilled .

Another disadvantage of the prototype method is that in it the speed of horizontal propagation of the ripple field, which characterizes the horizontal heterogeneity of the field of sources, is determined under the assumption of a horizontally uniform section. In this regard, this method is focused on a very low horizontal inhomogeneity of the cut, much lower than the heterogeneity of the source field, since the heterogeneity of the cut in the horizontal direction shifts the origin of the horizontal phase velocity of the pulsation field included in the cut impedance estimates. Therefore, this method is unacceptable in conditions of significant horizontal inhomogeneity of the section, when the horizontal inhomogeneity of the section becomes comparable with the horizontal inhomogeneity of the source field, as the accuracy and reliability of measurements drops sharply.

The claimed invention relates to geoelectromagnetic method magnetotelluric soundings. At present, measurements of the vertical electrical component are practically not carried out with magnetotelluric soundings. For a stable and reliable measurement of such a component, it is necessary to dig into wells that are available in an uncased state in exceptional cases. At the same time, the absence of measured data E _z dramatically reduces the possibility of MTZ in the study of lateral heterogeneities in the mantle and in the upper layers of the earth's crust. This is clearly demonstrated in FIG. 4, where the anomalous effect of the presence of heterogeneity is very weak in the measured horizontal electrical component on the surface, and the vertical component is entirely determined by the heterogeneity.

In the claimed technical solution for fixing the vertical electrical component, the measuring device is performed according to the circular electric dipole scheme (see FIG. 2).

The problem solved by the claimed invention is to increase the efficiency and expand the use of magnetotelluric soundings in identifying weak lateral inhomogeneities.

The technical result of the claimed invention is to significantly increase the dependence of the received signals from the horizontal heterogeneity of the section and the associated efficiency of the electromagnetic soundings of the Earth when weak lateral inhomogeneities are detected.

The claimed technical result is achieved through the use in the claimed method of electrical exploration to study the three-dimensional geological structures of the measuring device to highlight the vertical electrical component in a natural magnetotelluric field, made according to the circular electric dipole scheme, which have horizontal radial grounded lines converging to the center at equal angular intervals , with a radius corresponding to the depth of the research, and grounded at the outer ends and in common m central electrode.

In the particular case of the implementation of the claimed method mentioned measuring device is located on the sea surface. Technical implementation follows from the known method of direct search for local objects on the shelf of the World Ocean according to the patent of the Russian Federation No. 2116658, in which a circular electric dipole is located on the sea surface with the help of floating buoys equipped with electric motors and propellers. The geometry of the entire installation is supported with the help of cables connecting the buoys with the vessel and among themselves. In this case, the central electrode is lowered into the water from the vessel, and the external electrodes, electrically connected to the center by insulated wires along radial cables, are lowered into the sea water from the buoys.

In the particular case of the implementation of the claimed method mentioned measuring device is located on a drifting ice floe. The technical implementation follows from a known method of marine electrical prospecting and a device for its implementation in accordance with the patent of Russian Federation No. 2434251, in which in one of the options it is proposed to arrange a circular electric dipole on a drifting ice floe, grounding the electrodes in sea water through holes in the ice. At the same time, the external electrodes and, respectively, through the holes in the ice are evenly spaced around the circumference (radius of QED), and in the center of the circle, the central electrode is grounded through the hole in the ice. The external electrodes are connected by insulated wires located on ice strictly radially in the central part of the installation, where the emf is measured between the central electrode and the common end of the radial lines from the external electrodes.

Details, features, and advantages of the present invention follow from the following description of the embodiments of the claimed technical solution using the drawings which show:

FIG. 1 - vertical current sounding method.

FIG. 2 - measuring device according to the circuit of a circular electric dipole.

FIG. 3 - vertical electrical component and the signal from the measuring device according to the QED scheme.

FIG. 4 - Comparison of conventional measurements on the surface and the signal from the vertical line.

The invention characterizes geoelectromagnetic surveying by the method of magnetotelluric soundings using the TM-polarized electromagnetic field in geoelectromagnetic exploration, the receiver of which is the measurement configuration according to the circular electric dipole scheme.

A circular electric dipole (QED), as you know, is a set of horizontal radial grounded at the ends of the lines, one end of which is located in the center of the circle, and the other end is on a circle, while maintaining the condition that all lines are at the same angular distance from each other and in the known technical solution the electric current supplied to the lines is the same at any time.

Within the work area, a small QED installation is installed in the form of, usually, eight, horizontal, grounded lines, converging to the center at an angle of 45 degrees, with a radius (length of lines) corresponding to the depth of investigation. Within the site, a magnetotelluric field is measured in various magnetic and electrical components. In particular, to realize the advantages of using the TM-polarized field, the QED installation is used as a measuring one. Measure the potential difference between the central electrode and the external. This potential difference is converted to the value of E _z at the effective depth under QED.

In the claimed technical solution, the measuring device in the form of QED allows to estimate the vertical component of the electric field in any place, without using wells.

The claimed method magnetotelluric soundings for the study of geological structures includes the steps in which:

within the area of work, a receiving installation is arranged in the form of a circular electric dipole,

provide a measurement of the radial potential difference, which significantly increases the information content of the work compared to existing methods, which measure only horizontal electrical components,

the results are judged on the magnitude of the vertical electrical component, which directly indicate the deep heterogeneity of the geological environment.

The advantages of the claimed method in the use of QED as a receiver:

1) with such work there is no need for wells;

2) the results obtained, depending on the radius of QED, refer to different depths and are additional soundings;

3) the measurements obtained in this way, in contrast to the traditional methods of MTZ, make it possible to directly and directly judge the lateral heterogeneities in the section, without requiring extensive areal observations.

In an embodiment of the inventive method, a measuring device in the form of QED is placed on the sea surface.

In an embodiment of the inventive method, a measuring device in the form of QED is disposed on the surface of drifting ice.

The effectiveness of the proposed method is associated with the proven efficiency of applying the TM-polarized field in the form of a new electrical prospecting method - vertical current sounding (SVT), conventionally represented in FIG. one.

FIG. 2 shows a diagram of the device of the measuring device in the form of QED.

FIG. 3 shows a comparison of the vertical electrical component and the signal from the measuring device according to the QED scheme.

FIG. 4 shows a comparison of conventional measurements on the surface and the signal from the vertical line.

Let us show how our proposal is implemented with the help of three-dimensional mathematical modeling. Firstly, in FIG. 3 shows a comparison of the curves of the signals from the vertical line and the receiving unit on the surface according to the QED scheme. The medium is a homogeneous half-space with a specific electrical resistance of 100 Ohm * m. At a depth of 12.5 km there is a conducting heterogeneity with a resistance of 10 Ohm * m. Measurements are taken at the point indicated by a cross. Curves are presented depending on the frequency of the magnetotelluric field. Up to a certain technical factor, the curves are close and coincide at low frequencies. Receiving installation of QED, installed on the surface, really allows us to estimate the vertical component of the electric field at depth.

We now show that the vertical component of the electric field, if it is measured, does indeed increase the efficiency of magnetotelluric soundings. FIG. 4 shows a comparison of conventional measurements on the surface and the signal from the vertical line along the profile. It is seen that the anomalous effect of the presence of inhomogeneity is very weak in the measured horizontal electrical component on the day surface, and the vertical component changes radically by several orders of magnitude.

The claimed technical result is achieved through the use in the claimed method of electrical exploration to study the three-dimensional geological structures of the measuring device to highlight the vertical electrical component in a natural magnetotelluric field made according to the circular electric dipole scheme for which horizontal radial grounded lines are arranged, converging to the center at equal angular intervals, with radius corresponding to the depth of research, and grounded at the outer ends and the common central electrode.

In the particular case of the implementation of the claimed method mentioned measuring device is located on the sea surface. Technical implementation follows from the known method of direct search for local objects on the shelf of the World Ocean according to the patent of the Russian Federation No. 2116658, in which a circular electric dipole is located on the sea surface with the help of floating buoys equipped with electric motors and propellers. The geometry of the entire installation is supported with the help of cables connecting the buoys with the vessel and among themselves. In this case, the central electrode is lowered into the water from the vessel, and the external electrodes, electrically connected to the center by insulated wires along radial cables, are lowered into the sea water from the buoys.

In the particular case of the implementation of the claimed method mentioned measuring device is located on a drifting ice floe. The technical implementation follows from a known method of marine electrical prospecting and a device for its implementation in accordance with the patent of Russian Federation No. 2434251, in which in one of the options it is proposed to arrange a circular electric dipole on a drifting ice floe, grounding the electrodes in sea water through holes in the ice. At the same time, the external electrodes and, respectively, through the holes in the ice are evenly spaced around the circumference (radius of QED), and in the center of the circle, the central electrode is grounded into the sea water through the hole in the ice. The external electrodes are connected by insulated wires located on ice strictly radially in the central part of the installation, where the emf is measured between the central electrode and the common end of the radial lines from the external electrodes.

Claims (3)

1. A magnetotelluric sounding method for studying geological structures, in which multidirectional electrical and magnetic components of a magnetotelluric field are measured at the surface of the Earth, which determine the partial impedances of magnetic and electrical type waves and judge the distribution of the conductivity of a horizontally layered section of the earth's crust in the upper mantle, characterized by that a measuring device for isolating a vertical electrical component in a natural magnetotelluric field is performed It is built according to the circular electric dipole scheme, for which horizontal radial earthed lines are arranged, converging to the center at equal angular intervals, with a radius corresponding to the depth of research, and grounded at the outer ends and with a common central electrode. 2. The method according to p. 1, characterized in that the said measuring device is located on the surface of the sea using floating buoys. 3. The method according to p. 1, characterized in that the said measuring device is located on a drifting ice floe, and the electrodes are grounded through holes in the ice.

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